Connected Moments and Quantum Computing Improve “Many Body” Chemical Simulations
Using the connected moments mathematical technique decreases the time and computational power needed for quantum computing simulations of chemical systems.
Using the connected moments mathematical technique decreases the time and computational power needed for quantum computing simulations of chemical systems.
Liquid acts across multiple scales to reorganize connectivity in networks of artificial microscopic cells.
Using cold temperatures and machine learning, researchers visualized individual molecules in a synthetic soft material for the first time.
Actinide tetrafluorides exhibit significant variations in their electronic structures despite having nearly identical crystal structures.
Microscopic features of neptunium dioxide control how contaminants dissolve in underground disposal of spent nuclear fuel.
Scientists engineer materials’ electrical and optical properties with plasmon engineering
A unique coating camouflages the temperature of an underlying material
Nanotubes with designed defects allow better performance for next-generation optical telecommunications.
A team of Molecular Foundry researchers directly visualized and measured excitons hopping across very long distances.
A material with a disordered rock salt structure could help make batteries safer, faster-charging, and able to store more energy
Scientists discover a high-resolution X-ray fluorescence probe to measure nanostructures in thin films.
State-of-the-art techniques expand scientists’ fundamental understanding of heavy element 99, Einsteinium.